OA12814A - Système de colonne mo ntante flexible. - Google Patents

Abstract

The invention concerns a riser system connecting a stationary underwater installation to a floating surface unit, comprising at least one flexible pipe (10) in catenary configuration and extending between the surface installation (2) and an immersed buoy (5), at least one riser pipe (11) in catenary configuration between said buoy (5) and the sea floor (6) said buoy (5) being anchored on the sea floor through an anchoring device (9) including at least two tensioned anchoring lines (7, 8). The invention is characterized in that it comprises at least two mooring lines (18, 19) in catenary configuration whereon are provided return means (12 to 14) which exert on said buoy (5) a return force which depends of the lateral displacement of the buoy (5). The invention is applicable to offshore oil drilling.

Description

1 012814

The present invention relates to a riser system (Riser Tower System in English) for connecting a fixed subsea installation such as a wellhead or manifold to a flotation surface unit such as a platform or a ship FPSO type (FloatingProduction Storage and Offloading). 'Exploitation of an offshore oil field (Offshore) is becoming more complex as the significant water depths which today can reach several thousand meters. The transfer of product from the fixed installation, located on the seabed and formed especially by a wellhead, to the unit or installation of floating surface, raises a number of difficulties. The most commonly used transfer systems are so-called Riser Tower Systems, which include ducts in which various products are transported between the seabed and the surface, such products being, for example, , water, etc ... .Other pipes can also be used including lines of fluid injection, loading or electrical and / or hydraulic control.

In petroleum operations in particular where the deposits are at great depths, turbulence zones that are between 50 and 300 m below the surface of the water may have effects not only on the installation or unit of surface that This can be caused by waves and other phenomena such as pitch, roll, etc., but also on the riser system, which is subject to waves, wind, and sea currents.

As a result, the riser systems are designed to withstand these stresses, which can be more or less important. Various types of riser systems have been proposed and are described, for example, in US 3,111,692, 3,677,302, 4,031,919, 4,188,156, 156,182,584, 4,388, 022,4,400,109 and 4,423,984. .

The main disadvantages of these systems are that it is necessary to use buoys with a high buoyancy of at least 2000 tonnes when this buoyancy is distributed over the entire climbing column, the elements of the buoy must bear 'importantespressions. Another disadvantage is that these systems are manufactured on the ground and must then be brought and installed on the site, all of these operations being delicate and expensive. Moreover, it is very difficult to anchor the ends of the rigid sections on the seabed without using divers or very sophisticated machines such as the ROV (RemoteOperated Vehicle), which entails a significant cost of setting up. and monitoring during the exploitation of the deposit.

In US 5,639,187 there is disclosed a system which combines rigid pipes and flexible pipes to effect fluid communication between the fixed subsea installation and the surface unit, the system including a submerged buoy which is anchored to the bottom. at least four anchored anchor lines, each of the anchor lines being attached to the ends of the buoy and to a top of a kind of rectangle 25 formed on the seabed, so as to minimize the rotation of the buoy which could be caused by horizontal forces and the weight of the escapes extending between the buoy and the seabed. In fact, the system is of the "tension leg" type which must withstand vertical loads of at least T 500 tonnes and even more to take up, especially during installation, the buoyancy of the engine. the buoy which must be greater than the weight of the pipes in large numbers in such exploitation. The submerged buoy must also have a reserve floppy to give the entire system stiffness necessary to limit its lateral movements. Indeed, the lateral movements of the buoy are undesirable because they can bend the rigid pipes to rays such that they can plastically deform the pipes and thus create a crush primer by ovality at the zone of inflection ( Sag Bend in English). The inflection zone is located above the contact zone of the pipes on the seabed, said contact zone being usually called the Touch Down Point (TDP).

The object of the present invention is to propose at least one riser or Riser Tower System which is more adapted to the movements of the surface unit, simple to produce and to put in place and less expensive than the systems of the prior art. comparable operating conditions.

An object of the present invention is a riser system designed to connect a subsea installation fixed to a surface unit, the type comprising at least one flexible pipe disposed catenary and extending between the surface installation and a submerged buoy, at least one riser (Riser in English) disposed catenary between saidbouée and the seabed, said buoy being anchored to the seabed parK intermediate an anchor device comprising at least two tensioned anchor lines, and which is characterized in it comprises at least two catenary mooring lines and on which are provided recall means which exert on said buoy a restoring force that depends on the lateral movement of said buoy.

An advantage of the present invention lies in the fact that, when the submerged buoy moves laterally, it is automatically called back to its initial or equilibrium position by the means of which the force is variable, i.e. develop a call force that depends on the amplitude of the lateral movement of the buoy.

According to another characteristic of the invention, the recall means consist of a ballast which is distributed on either side of the contact point or zone of the mooring line on the seabed. The weighted portion of the mooring line, located above the point of contact, in the direction of hitching, is primarily the restoring force. Such a structure is simple to achieve since the ballast can be of any kind such as chains, balls, weights or pigs. In addition, it is easy to determine in advance the "return" length of the mooring line, that is to say the length of the weighted part. Finally, it is possible to ballast a longer length, than that which is necessary, of the line portion resting on the seabed if one does not wish to anchor the end of the docking line. In such a case, care must be taken that the line of mooring does not move too much and does not get entangled in the tight anchor lines of the buoy.

According to another characteristic, each mooring line is connected to the buoy by a flange or crowbar which is arranged below the ground and which is intended to prevent or at least limit the rotation of the buoy. Other advantages and features will be apparent from the following description of an embodiment of the present invention, as well as appended drawings in which:

Figure 1 is a schematic elevational view of the ascending column system according to one embodiment of the invention. FIG. 2 is a diagrammatic elevational view of the riser system for several lateral positions of the buoy. The column system 1, diagrammatically shown in FIG. 1, is intended to connect a fixed underwater installation 2, constituted for example by a wellhead, a manifold or other collector and delivering a product coming from a petroleum deposit or other, to a floating surface unit or installation 3 such as a platform or an FPSO, the distance separating the surface 3 and underwater installations 2 may reach several thousand meters. At a certain distance from the surface of the water and generally beyond the turbulence zone of the concerned water layer, a buoy 5 is immersed which is anchored to the seabed by two anchor lines 7, 8 ("Tether" in English) which are stretched between the buoy 5 and a dead body 9 or other means of anchoring (suction pile).

One or more flexible lines 10 extending catenary between the surface unit 3 and the buoy 5 are connected to one or more risers 11 (Riser in English), which extend catenary between the buoy 5 and the installation fixed submarine 2, so that fluid communication is established between said installations 2 and 3. The upstream conduits extending catenary from the buoy to the seabed can be of any type as rigid -onductors commonly called SCR (Steel Catenary 35 Riser), single or double jacket (Pipe in Pipe) and even flexible lines or hybrid lines having at least one flexible part and a rigid part.

The riser tower system comprises at least two mooring lines 18, 19 disposed in catenary between the buoy 5 and the seabed 6. Each docking line 18, 19 comprises in the lower portion 14 a portion 13 which is ballasted by a ballast 12. This ballast 12 constitutes return means for hooked, the restoring force depending mainly on the lateral movement that could have said buoy 5 and whose cause can be originated o o strong swell, marine currents and more generally the displacements of the surface unit 3. The weights 12 are distributed on each side of the contact zone 15 (Touch Down Point in English) which is the zone or the point, where the line of mooring joins the seabed 6. The weights 12 can be formed by weights, balls, chains or pigs. The weights are distributed on either side of the contact zone when the buoy is in its equilibrium position (center position A of FIG. 2). 4 In the position A which corresponds to that of FIG. 1, the mooring lines 7, 8 are substantially vertical and the weighted parts 13 of the mooring lines 18, 19 rest for the most part on the seabed. position C, the weighted parts 13 rely more on the seabed while in position B, the weighted parts 13 are raised and develop a restoring force that tends to bring the system to the position A, the restoring force being variable depending the weighted length which is raised from the seabed by the movement of the corresponding mooring line, movement induced by the lateral displacement of the buoy 5 (Figure 2). By way of example, the weight of each mooring line 18, 19 is constituted by 4-inch (-10 cm) chains which are distributed over 100 m, knowing that when the buoy 5 is at the midpoint ( vertically), about one-third of the ballast is raised from the ground and produces a tension of about 50 tons in each mooring line 18, 19. Of course, these indications are given only as an example, the choice and the arrangement of the elements constituting the ballast depends on the particular case envisaged. However, it is possible to indicate that the weight per unit of length that is set to ballast the catenary line 18, 19 depends in particular on the distance between the buoy 5 and the seabed 6.

Each tethered anchor line 7, 8 is attached to a top 16 of a flange or crowbar 17 which is attached to the buoy at one end of the latter, and which is also intended to prevent or greatly limit the rotation of the buoy . The points of attachment of the anchoring lines 7, 8 to the flanges 17 are preferably substantially in the median plane passing through the longitudinal axis 18 of the buoy 5. In FIG. 1, the median plane comprising the anchoring lines 7, 8 is materialized by the XX points.

Each mooring line 18, 19 is connected to one end 20 of knuckle 5 which is opposite the other lateral end 21 to which is connected or rising pipes ("Riser" in English). It can also be connected to the top 16 of the flange 17, so that the points of attachment of the mooring line 18, 19 are located substantially in the median plane in which are located the points of attachment to the buoy 5 of the starter lines 7, 8.

In a preferred embodiment of the invention, the buoy 5 is variable buoyancy and comprises several parts, for example three parts 22 to 24 each consisting of a hollow cylinder. Such a structure of the buoy 5 avoids having to develop very important forces at buoy 5, which forces dependsnotamment the number and weight of risers that will be provided between the seabed 6 and said buoy 5. Indeed Thanks to the compartmentalization of the buoy 5, each cylinder 22 to 24 constitutes a compartment which can be partially or totally emptied as the risers are installed. Thus, in a first phase, the compartments are filled with a suitable fluid such as water. Then, after the installation of the first riser, part of a compartment is emptied and filled with gas, the amount emptied depending on the weight of the riser posed. The procedure is carried out sequentially and in the same way for the other ascending conduits.

According to the described embodiment of the invention, the conduitmontantes 11 (Riser in English) are connected to the flexible pipes

V 0128 14 associated 10 by connections by tip in a manner known per se. These risers 11 are supported by the buoy by a device of receptacle connection and suspension schematically shown in Figure 1 and referenced 30, wherein their end cap is housed. It may be noted that this device may comprise damping means intended to allow the risers a certain angular deflection relative to the buoy at their connection.

Claims (10)

A riser system (1) for connecting a stationary marine system (2) to a floating surface unit (3), of the type comprising at least one flexible pipe (10) arranged in a catenary and extending between surface installation (2) and a submerged buoy (5), at least one riser (11) disposed catenary between said buoy (5) and the marine base (6), said buoy (5) being anchored to the seabed by intermediate of an anchoring device (9) comprising at least two tensioned anchoring lines (7, 8), characterized in that it comprises at least two catenary lines (18, 19) and which return means (12 to 14) are provided which exert on said buoy (5) a return force which depends on the lateral movement of said buoy (5). 2. riser system according to claim 1, characterized in that the return means are constituted by at least one ballast (12) disposed on the lower portion of each mooring line (18,19). 3. Riser system according to claim 2, characterized in that the ballast (12) is distributed on either side of the contact zone (15) of the mooring line (18, 19) on the seabed. (6). 4. riser system according to claim 3, characterized in that the portion (13) of the ballast situated above the contact zone (15) constitutes the restoring force. 5. riser system according to claims 1 and 2, characterized in that each mooring line (18,19) is connected to the buoy 30 (5) via a lug (17) disposed below the buoy (5), said tab (17) preventing the rotation of said buoy (5). 6. riser system according to claim 1, characterized in that the taut anchor lines (7, 8) are located substantially in the median plane (X-X) passing through the longitudinal axis of said buoy (5). -V '012814 7. riser system according to claim 2 or 5, characterized in that the buoy (5) is variable buoyancy and consists of several parts (22 to 24). An riser system according to claim 2 or 5, characterized in that each mooring line (18, 19) is connected to one end (20) of the buoy (5) which is opposed to the other side end. (21) to which the riser pipe (11) is connected. 8 012814 CLAIMS 9. riser system according to claim 2 or 5, characterized in that each mooring line (18, 19) is connected to the buoy 10 immersed at a point (16) located substantially in the median plane (X-X). 10. A method for producing a riser system (1) between an underwater installation (2) and a floating surface installation (3), which is responsible for immersing a buoy (5) which is connected to the surface installation by at least one a flexible duct (10) arranged in a catenary and which is anchored to the seabed (6) by at least two tensioned anchor lines (7, 8), to have at least one catenary riser (11) between said bugee and the seabed, characterized in that it consists in exerting on the knuckle (5) return means whose force depends on the lateral movement of said buoy.